Aeroplane equipped with an internal escape hatch having a double opening controller

ABSTRACT

An aeroplane includes an escape opening passing through an external skin and an internal bulkhead. The escape opening is closed off by an external escape hatch having an external opening controller. The aeroplane further includes an internal escape hatch that closes off said escape opening flush with the internal bulkhead, and kept closed by at least one catch movable between a locked state and unlocked state, a first opening controller that controls the passage from the locked state to the unlocked state of the catch being accessible from inside the aeroplane, and a second opening controller that controls the passage from the locked state to the unlocked state of the catch being positioned such that the actuation of the external opening controller of the external escape hatch or the passage of the external escape hatch from the closed position to the open position causes the second opening controller to be actuated.

FIELD OF THE INVENTION

The present invention relates to an aeroplane equipped with an internal escape hatch having a double opening controller.

BACKGROUND OF THE INVENTION

As illustrated in FIG. 2, an aeroplane comprises a skin 10 that forms the fuselage, a passenger cabin (not shown) delimited by an internal bulkhead, and a pilot cabin 12 delimited by an internal bulkhead 14. Various components are disposed between the skin 10 and the internal bulkhead 14, for example insulation blankets 16.

In order to evacuate the passengers and/or the pilots, the aeroplane comprises an opening 18 for bringing the inside of the cabin 12 into communication with the outside 20 of the aeroplane, and at least one escape hatch 22 for closing off or freeing the opening 18. According to an example that is visible in FIG. 1, this escape hatch 22 is positioned in the upper part of the fuselage, vertically above the pilot cabin 12. This escape hatch 22 comprises a wall having an external surface 24 flush with the external surface of the skin 10 of the fuselage. This escape hatch 22 comprises locking/unlocking means 25 that are controlled by an internal opening controller 26 that is actuable from inside the fuselage, and by an external opening controller 28 that is actuable from outside the fuselage. Inside the fuselage, at the opening 18, it is necessary to provide a lining element 30 in the opening 18 against the escape hatch in order to ensure the continuity of the internal bulkhead 14 of the cabin 12.

This lining element 30 should be secured correctly in order not to fall accidentally. However, it should be able to be removed rapidly in the event of an emergency evacuation, in order to allow access to the escape hatch 22 from the inside. According to another constraint, it should be possible to remove this lining element 20 with one hand.

Finally, in the event of intervention from the outside, it should be possible to remove the lining element 30 from the outside.

Thus, the present invention proposes a solution that aims to meet at least these constraints.

BRIEF SUMMARY OF THE INVENTION

To this end, a subject of the invention is an aeroplane comprising an external skin and an internal bulkhead delimiting a cabin, and comprising an escape opening passing through said external skin and said internal bulkhead, said escape opening being closed off by an external escape hatch that is movable between a closed position, in which it is disposed flush with the external skin, and an open position, said external escape hatch comprising locking/unlocking means that are controlled by an external opening controller, characterized in that the aeroplane comprises:

an internal escape hatch that closes off said escape opening flush with the internal bulkhead,

at least one catch that is movable between a locked state and an unlocked state, said catch keeping said internal escape hatch in a closed position in the locked state,

a first opening controller that controls the passage from the locked state to the unlocked state of the catch being accessible from inside the aeroplane,

a second opening controller that controls the passage from the locked state to the unlocked state of the catch being positioned such that the actuation of the external opening controller of the external escape hatch or the passage of the external escape hatch from the closed position to the open position causes the second opening controller to be actuated.

According to an embodiment of the invention, the internal escape hatch makes it possible to close the escape opening at the internal bulkhead. By virtue of the catch, this internal escape hatch is kept in the closed position in a reliable manner. Finally, this internal escape hatch comprises a double controller for opening said hatch from the inside of the aeroplane but also from the outside.

Advantageously, the second controller comprises a pivoting lever, and a cable which connects said lever to the catch, said lever and said cable being configured such that, during the actuation of the external opening controller of the external escape hatch or during the passage of the external escape hatch from the closed position to the open position, the lever pivots and exerts a traction force on the cable, causing the catch to pass from the locked state to the unlocked state.

According to another feature, the internal escape hatch comprises at least one return means which causes the catch to tilt into the unlocked state, and at least one locking handle that is movable between a first position corresponding to the locked state of the catch, in which the locking handle immobilizes the catch counter to the one or more return means, and a second position in which the locking handle does not immobilize the catch, which tilts into the unlocked state by virtue of the one or more return means.

According to another feature, the internal escape hatch comprises at least one return means for keeping the locking handle in the first position.

Preferably, the catch comprises at least one arm fixed to a shaft that pivots about a rotation axis with respect to a holder connected to the internal escape hatch, said rotation axis and the arm being configured such that in the locked state, the arm or an element carried by the arm is in contact with a stop, and such that in the unlocked state, the arm or an element carried by the arm is spaced apart from the stop and allows the internal escape hatch to be opened. According to one embodiment, the shaft comprises at least one notch and the locking handle comprises at least one protrusion which bears against the notch of the shaft in the locked state.

According to another feature, the locking handle is able to rotate about a rotation axis and comprises a controller that is spaced apart from the rotation axis by a distance greater than the protrusion(s).

Preferably, the cable of the second controller is connected to the locking handle.

According to another feature, the internal escape hatch comprises pressure regulating means which automatically trigger the opening of said internal escape hatch when a pressure difference on either side of said hatch exceeds a given value.

Advantageously, the internal escape hatch is connected to the aeroplane by at least one strap which comprises a ring, and the shaft which supports the catch comprises, for each strap, a hook having an end which bears against a bearing surface when the catch is in the locked state and which is spaced apart from said bearing surface when the catch is in the unlocked state, the hook passing through the ring in the locked state.

BRIEF DESCRIPTION OF THE DRAWINGS

Further features and advantages will become apparent from the following description of the invention, said description being given purely by way of example, with reference to the appended drawings, in which:

FIG. 1 is a perspective front view of an aeroplane, illustrating an external escape hatch,

FIG. 2 is a schematic section through an escape opening, illustrating the prior art,

FIG. 3A is a schematic section through an escape opening, illustrating the invention,

FIG. 3B is a section illustrating a detail of FIG. 3A,

FIGS. 4A to 4C are diagrams which illustrate the principle of operation of an internal escape hatch that is actuated from the inside,

FIG. 5 is a perspective view from the outside of an internal escape hatch, illustrating one embodiment of the invention,

FIG. 6 is a section through a control mechanism for the movement of a catch illustrated in FIG. 5,

FIG. 7 is a perspective view which illustrates in detail the control mechanism for the movement of the catch,

FIG. 8 is a perspective view of a first disconnect of hinge, illustrating one embodiment of the invention,

FIG. 9 is a perspective view of a second disconnectable hinge, illustrating one embodiment of the invention,

FIG. 10 is a diagram which illustrates the principle of operation of an internal escape hatch that is actuated from the outside,

FIG. 11 is a perspective view which illustrates in detail a lever that is actuable by way of an external opening controller for an external escape hatch,

FIG. 12 is a perspective view which illustrates in detail the control mechanism for the movement of the catch when it is actuated from the outside,

FIG. 13 is a diagram which illustrates depressurization of a pilot cabin of an aeroplane,

FIGS. 14A and 14B are sections through the control mechanism for the movement of the catch during depressurization of a pilot cabin,

FIG. 15 is a front view which illustrates the internal escape hatch after opening on account of depressurization of the pilot cabin,

FIG. 16 is a perspective view which illustrates in detail a centring pin that is used to position the internal escape hatch,

FIGS. 17A and 17B are views of the external face of an internal escape hatch before and after an overpressure in the pilot cabin,

FIG. 18 is a side view of the water-absorbing element,

FIG. 19 is a perspective view of a lug for holding an overpressure panel of an internal escape hatch,

FIG. 20 is a perspective view of a holder for a permanent magnet of an overpressure panel of an internal escape hatch, and

FIG. 21 is a perspective view of a permanent magnet of an overpressure panel of an internal escape hatch.

DETAILED DESCRIPTION

FIG. 3A shows a part of an aeroplane which comprises a fuselage with an external skin 40 attached to a structure 42, and, inside the fuselage, a cabin 44 delimited by an internal bulkhead 46 spaced apart from the skin 40.

As illustrated in FIG. 13, an aeroplane comprises a pilot cabin 44 provided at the front and a passenger cabin 44′ behind the pilot cabin 44, separated from the latter by a separating bulkhead 47 which comprises a door for bringing the cabins 44, 44′ into communication.

Each cabin 44, 44′ is delimited by an internal bulkhead 46. Various elements are interposed between the skin 40 and the internal bulkhead 46, such as insulation blankets, for example.

According to an embodiment that is illustrated in FIG. 3A, the aeroplane comprises at least one escape opening 48, which makes it possible to bring the inside of a cabin 44 into communication with the outside of the aeroplane and which opens out at the skin 40 forming the fuselage and at the internal bulkhead 46 of the cabin 44. Preferably, this internal bulkhead 46 extends, at least around the escape opening 48, approximately parallel to the skin 40 and at a distance from this skin. In one installation, the escape opening 48 leads onto the upper part of the fuselage. It is preferably positioned above the seat of the third occupant of the pilot cabin 44 or not quite vertically above this seat, as shown in FIG. 15. This installation is preferred since it affords better accessibility from the various positions on the pilot cabin.

For the rest of the description, as indicated in FIG. 1, a longitudinal direction DL corresponds to the direction which extends from the front tip to the rear tip of the aeroplane. A transverse plane is a plane perpendicular to the longitudinal direction. A radial direction DR is a direction perpendicular to the longitudinal direction.

In one configuration, the escape opening 48 is delimited by a perimeter comprising a front edge comprised in a first transverse plane, a rear edge comprised in a second transverse plane, a lower edge and an upper age parallel to the longitudinal direction and rounded portions connecting the front, rear, lower and upper edges.

However, the invention is not limited to this geometry for the perimeter of the opening.

The escape opening 48 is closed off by a removable external escape hatch 50 flush with the skin 40, said external escape hatch 50 having a geometry adapted to that of the escape opening 48 and comprising a wall with an external surface 52 flush with the external surface of the skin 40 of the fuselage when the external escape hatch 50 closes off the escape opening 48. The external escape hatch 50 comprises locking/unlocking means 54 that are controlled by an internal opening controller 56 that is actuable from inside the fuselage and by an external opening controller 58 that is actuable from outside the fuselage.

According to an embodiment illustrated in FIG. 10, the external escape hatch 50 is connected to the rest of the fuselage of the aeroplane by a pivot pin 60. When the locking/unlocking means 54 are in the unlocked state, the external escape hatch 50 can pivot about the pivot pin 60 towards the inside of the fuselage.

In another embodiment, the external escape hatch 50 carries an element which is moved towards the inside of the fuselage when the external opening controller 58 is actuated.

The external escape hatch 50 is not described further, since it can be identical to that of the prior art.

According to one feature of the invention, the aeroplane comprises, at the escape opening 48 and the internal bulkhead 46, an internal escape hatch 68 that is movable between a closed position, in which it closes off the escape opening 48, and an open position, in which it frees the escape opening 48. The internal escape hatch 68 comprises a rigid or semi-rigid panel 69 having an internal surface 70 disposed flush with the internal surface of the bulkhead 46 in the closed position, and an external surface 72 oriented towards the external escape hatch 50.

In one configuration, the aeroplane comprises a frame 74 which surrounds the escape opening 48 and which cooperates with the internal escape hatch 68, the periphery of which coincides with that of the frame 74, so as to obtain leaktightness between the frame 74 and said internal escape hatch 68. This frame 74 comprises an upper edge 76 and a lower edge 76′ that are approximately parallel to the longitudinal direction, and also a rear edge 78 in one transverse plane and a front edge 78′ in another transverse plane.

Preferably, as shown in FIG. 3B, the internal escape hatch 68 has shapes complementary to those of the frame 74 so as to limit the movement of the internal escape hatch 68 in the radial direction DR towards the outside of the aeroplane and to allow movements of the internal escape hatch 68 towards the inside of the aeroplane, on account in particular of the weight of the internal escape hatch 68.

According to one embodiment, the internal escape hatch 68 comprises a lip 80 which prolongs the internal surface 70 of said hatch 68 and which forms a contact surface 82 that is approximately perpendicular to the radial direction DR and bears against the frame 74 or the internal bulkhead 46 in the closed position. In addition, the frame 74 or the internal bulkhead 46 comprises an indentation 84 having a contact surface 86 against which the lip 80 bears when the internal escape hatch 68 is in the closed position, said indentation 84 being dimensioned to house the lip 80 and such that the internal surface 70 of the internal escape hatch 68 is flush with the internal surface of the bulkhead 46. According to one embodiment, the lip extends around the entire periphery of the internal escape hatch 68.

In one configuration, the internal escape hatch 68 has shapes complementary to those of the frame 74 or the internal bulkhead 46 so as to help the centring thereof with respect to the frame 74 or the internal bulkhead 46.

According to one embodiment, the internal escape hatch 68 has a peripheral edge face 88 in the form of a truncated pyramid, which helps in centring (visible in FIGS. 3B and 17A).

The internal escape hatch 68 comprises at least one catch 90 configured to take up a locked state in which the catch 90 keeps said internal escape hatch 68 in the closed position, and an unlocked state in which the catch 90 allows said internal escape hatch 68 to be opened, in particular under the effect of gravity.

In the locked state, the catch 90 cooperates with at least one stop 92 carried by the frame 74.

In one configuration, the stop 92 is positioned on the upper edge 76 of the frame 74, equidistantly from the rear and front edges 78, 78′. The stop 92 protrudes with respect to the upper edge 76 and extends towards the lower edge 76′ approximately perpendicularly to the longitudinal direction DL and to the direction DR.

The stop 92 is positioned with respect to the catch 90 so as to prevent the internal escape hatch 68 from moving when said catch 90 is in the locked state. According to the embodiment, the stop 92 is positioned under the catch 90 (offset towards the inside of the cabin) when the latter is in the locked state.

Regardless of the embodiment, the structure of the aeroplane comprises, for each catch 90, at least one stop 92 which immobilizes the catch 90 in a radial direction DR towards the inside of the aeroplane. Advantageously, the structure of the aeroplane comprises two stops, a first stop 92 which immobilizes the catch 90 in a radial direction DR towards the inside of the aeroplane and a second stop which immobilizes the catch 90 in a radial direction towards the outside of the aeroplane. According to one embodiment, the second stop corresponds to the contact surface 86 of the indentation 84 of the frame 74 or of the internal bulkhead 46.

Although it is described with a single catch, the internal escape hatch 68 may comprise a plurality of catches, each of which is associated with at least one stop.

Preferably, the catch 90 is able to rotate with respect to a rotation axis 94 approximately parallel to the longitudinal direction DL and to the direction DR. To this end, the internal escape hatch 68 comprises a pivoting connection with a rotation axis 94 for connecting the catch 90 to the panel 69 of the internal escape hatch 68, the rotation axis 94 being at a distance from the stop 92.

According to one embodiment, the connection between the catch 90 and the panel 69 comprises on the one hand a holder connected to the internal escape hatch 68 in the form of a yoke 96 having two cylindrical bearing surfaces 96 a and 96 b with coaxial axes coincident with the rotation axis 94, and on the other hand a shaft 98 which pivots in the two cylindrical bearing surfaces 96 a and 96 b and to which the catch 90 is connected.

The catch 90 comprises at least one arm 100 that is perpendicular to the rotation axis 94 and fixed rigidly to the shaft 98. The rotation axis 94 and the arm 100 are configured such that in the locked state, the arm 100 or an element carried by the arm is in contact with the stop 92, and in the unlocked state, the arm 100 or an element carried by the arm is spaced apart from the stop and allows the internal escape hatch 68 to be opened.

According to one embodiment, the catch 90 pivots about the rotation axis 94, in the anticlockwise direction, through an angle of around 120° between the locked state and the unlocked state.

According to an embodiment that is visible in FIG. 7, the catch 90 comprises two parallel arms 100. Advantageously, the catch 90 comprises at its end a roller 102 which is designed to roll on the stop 92. According to one embodiment, the two arms 100 carry at their free ends an axle on which the roller 102 is mounted in a pivoting manner.

Of course, the invention is not limited to these dynamics for the catch 90. Instead of pivoting, the catch could move in translation between a first position in contact with the stop 92, which corresponds to the locked state, and a position spaced apart from the stop 92, which corresponds to the unlocked state. However, the embodiment illustrated in the figures is preferred, since the rotation of the catch 92 about a rotation axis 94 makes it possible to obtain a lever effect.

The internal escape hatch comprises at least one mechanism for controlling the movement of the catch 90.

Preferably, this mechanism comprises at least one return means which causes the catch 90 to tilt in the unlocked state. According to one embodiment, the mechanism for controlling the movement comprises two springs 104, 104′ around the shaft 98, which cause the catch 90 to rotate in the unlocked state.

In addition to the one or more return means 104, 104′, the mechanism comprises at least one locking handle 106 which immobilizes the catch 90 in the locked state, counter to the one or more return means 104, 104′.

According to an embodiment that is visible in FIGS. 6 and 7, the shaft 98 comprises at least one collar 107 having at least one notch 108 at its periphery. This notch 108 has a contact surface passing through the rotation axis 94. Preferably, the shaft 98 comprises two collars 107, 107′ that are disposed in a symmetrical manner with respect to the catch 90, each of said collars 107, 107′ comprising a notch 108.

In addition, the locking handle 106 comprises at least one protrusion 110, one for each notch 108.

Preferably, the locking handle 106 is able to rotate about a rotation axis 112 between:

a first position corresponding to the locked state of the catch 90, in which the locking handle 106 prevents the catch 90 from rotating, the protrusion 110 of the locking handle 106 bearing against the notch 108 of the shaft 98, and

a second position, in which the locking handle does not prevent the catch 90 from rotating, the protrusion 110 being spaced apart from the notch 108 of the shaft 98.

Preferably, the rotation axis 112 is parallel to the rotation axis 94 of the catch 90.

According to one embodiment, the locking handle 106 is connected to the panel 69 by a pivoting connection which comprises:

a yoke 114 connected to the panel 69 with two cylindrical bearing surfaces 114 a and 114 b having coaxial axes coincident with the rotation axis 112,

a shaft 116 forming part of the locking handle 106 or connected to the latter, which pivots in the two cylindrical bearing surfaces 114 a and 114 b.

Preferably, the yokes 96 and 114 form a single assembly.

According to one embodiment, the locking handle 106 also comprises the shaft 116, two mutually parallel arms 118, 118′ that are perpendicular to the rotation axis 112, and a controller 120 in the form of a bar, the arms 118, 118′ connecting the shaft 116 and the controller 120, the arms 118, 118′ each being disposed in line with a notch 108 and comprising a protrusion 110.

At least one return means makes it possible to keep the locking handle 106 in the first position in which it prevents the catch 90 from rotating. According to one embodiment, two springs 123 are used as return means.

According to one configuration, the arms 118, 118′ carrying the protrusions 110 are offset towards the inside of the aeroplane with respect to the rotation axis 94. Thus, a traction force F towards the interior of the aeroplane that is exerted on the controller 120 causes the locking handle 106 to rotate, thereby freeing the catch 90, the latter pivoting into the unlocked state on account of the one or more return means 104, 104′.

The invention is not limited to these dynamics for the locking handle 106. Thus, instead of pivoting, the locking handle 106 could move in translation. However, the variant with a rotational movement about the rotation axis 112 makes it possible to obtain a lever effect, the controller 120 being spaced apart from the rotation axis 112 by a greater distance than the protrusion(s) 110.

The one or more return means 104, 104′ which cause the catch 90 to tilt into the unlocked state make it possible to separate the force necessary for causing the catch 90 to tilt from the force to be applied to the controller 120 in order to cause the locking handle 106 to rotate.

Thus, the invention makes it possible to reduce the traction force F exerted on the controller 120 in order to cause the change of state of the catch 90 and to cause the internal escape hatch 68 to open.

According to another feature of the invention, the passage of the catch 90 from the locked states of the unlocked state is controlled by two controllers, a first opening controller that is accessible from inside the aeroplane and a second opening controller that is connected to the external opening controller 58 of the external escape hatch 50, thereby making it possible to trigger the opening of the internal escape hatch 68 from outside the aeroplane.

The first opening controller comprises the catch 90 and locking handle 106 described above. They are disposed between the two hatches 50 and 68. Consequently, the panel 69 of the internal escape hatch 68 comprises an opening 122 for making the controller 120 accessible from inside the cabin.

Thus, as illustrated in FIGS. 4A to 4C, in order to open the internal escape hatch 68, a person should pass one hand through the opening 122 and then pull on the controller 120.

The second opening controller is situated between the external hatch 50 and the internal escape hatch 68. It is positioned such that the actuation of the external opening controller 58 of the external escape hatch 50 or the passage of the external escape hatch 50 from the closed position to the open position causes the second opening controller to be actuated.

The second opening controller comprises a lever 124 connected to the locking handle 106 by virtue of a cable 126.

According to an embodiment shown in FIGS. 10 and 11, the lever 124 pivots about a rotary pin 128 secured to the panel 69 by way of a holder 130 fixed to its external surface 72.

The lever 124 comprises a first end 132 positioned so as to be in contact with the external escape hatch 50 or an element carried by said hatch when the external opening controller 58 of the external escape hatch 50 is actuated.

According to one embodiment, the cable 126 is secured to the second end 134 of the lever, the first and second ends 132 and 134 of the lever being disposed on either side of the rotation axis 128, the first end 132 being further away from the rotation axis 128 than the second end 134 in order to obtain a lever effect.

The cable 126 and the lever 124 are arranged such that when the lever 124 tilts, it exerts a traction force on the cable 126.

As indicated above, the cable 126 comprises a first end connected to the lever 124 and a second end connected to the locking handle 106.

According to an embodiment illustrated in FIGS. 11 and 12, the cable 126 is inserted into a sleeve 135 which comprises a first end that is locked by a first holder 136 secured to the panel 69 and close to the locking handle 106, and a second end locked by a second holder 138 secured to the panel 69 and close to the lever 124. At the exit from the second end of the sleeve 135, the cable 126 is parallel to the rotation axes 94 and 112, in line with the controller 120. The panel 69 comprises a turn element 140 so as to orient the cable 126 in a direction perpendicular to the rotation axes 94 and 112 and to the controller 120. Preferably, the locking handle 106 comprises a lug 142 disposed at one end of the controller 120 and perpendicular thereto, the cable 126 being connected to said lug 142.

At the exit from the first end of the sheet 135, the cable 126 is oriented parallel to the rotation axis 128 of the lever 124. The panel 69 comprises a turn element 144 for orienting the cable perpendicularly to the rotation axis 128 of the lever 124 in the pivoting plane of the lever 124.

As illustrated in FIGS. 10 to 12, when the external opening controller 58 of the external escape hatch 50 is actuated, the external escape hatch 50, or an element carried by said hatch, exerts a force on the first end 132 of the lever 124. As a result of this force, the lever 124 pivots as illustrated in FIG. 10. The pivoting of the lever 124 causes a traction force on the cable 126, as illustrated in FIG. 11. The traction force exerted at the first end of the cable 126 is converted at the second end of the cable into a traction force on the locking handle 106, which pivots. By pivoting, the locking handle 106 frees the catch 90, which pivots into the unlocked state. The internal escape hatch 68 is then open.

The second opening controller for controlling the passage of the catch from the locked state to the unlocked state is not limited in this embodiment. Regardless of the variant, the second opening controller comprises a lever 124 that is actuable by the external escape hatch 50 and connected to the catch 90, the pivoting of the lever 124 during the opening of the external escape hatch 50 causing the catch 90 to pass from the locked state to the unlocked state.

In one configuration, the upper edge 76 of the frame 74 comprises a stop 92 which cooperates with a catch 90 secured to the panel 69 of the internal escape hatch 68. In addition, the panel 69 comprises two disconnectable hinges at the lower edge 76′. Each disconnectable hinge comprises a finger 146 which engages with a housing 148 provided at the rear edge 76′ of the frame 74, as illustrated in FIGS. 5, 8 and 9.

As shown in detail in FIG. 8, each finger 146 comprises, at a first end, a mounting plate 148 fixed to the panel 69 and, at the other end, a cylindrical form 150 (visible in FIG. 9) having an axis 152 parallel to the rotation axis 94 of the catch 90. At least one housing comprises two side walls 154, 154′ which prevent movement in translation in a direction parallel to the axis 152 of the cylindrical form 150 of the finger 146.

Thus, in order to be able to release the internal escape hatch 68 of the opening, it is appropriate, firstly, to tilt the catch 90 into the unlocked state so as to allow said hatch to pivot slightly about the axis 152 of the cylindrical forms 150, which then carry out the function of hinges. By continuing, as illustrated by the arrows 156 in FIGS. 8 and 9, the fingers 146 are disengaged from their housings 148. Consequently, the internal escape hatch 68 is opened and releases the escape opening 48.

According to another feature, the internal escape hatch 68 carries out the function of pressure regulator and opens automatically when a pressure difference on either side of the internal escape hatch 68 exceeds a given value. To this end, it comprises pressure regulating means which automatically trigger the opening of said internal escape hatch 68 when a pressure difference becomes too high on either side of said hatch 68.

Thus, according to a first function, the internal escape hatch 68 automatically opens in the event of depressurization of the pilot cabin 44, as shown in FIG. 13.

To this end, the stop 92 is retractable. As illustrated in FIGS. 6, 14A and 14B, the stop 92 is movable between a protruding position illustrated in FIG. 6, in which it retains the catch 90 and prevents the internal escape hatch 68 from being opened, and a retracted position, illustrated in FIG. 14A, in which it no longer retains the catch 90 and allows the internal escape hatch 68 to be opened. According to one embodiment, the stop 92 slides in a cylindrical bush 158 provided in the upper edge 76 of the frame 74, with a sliding axis A158 approximately perpendicular to the longitudinal direction DL and to the direction DR.

The stop 92 comprises a return means 160, for example a compression spring, which pushes the stop 92 into the protruding position. In parallel, the stop 92 and the bush 158 have complementary shapes in order to prevent the movement in translation of the stop 92 when it reaches the protruding position.

The return means 160 is set depending on the pressure difference necessary to cause automatic triggering of opening of the internal escape hatch 68. By way of example, in the embodiment shown, the pressure difference which triggers opening is between 6 and 9 millibars.

Advantageously, the stop 92 comprises a front face 162 having a bevelled, inclined first surface 164 which makes it possible to convert a crushing force of the catch 90 perpendicular to the sliding axis A158 into a movement of the stop 92 along the sliding axis A158 counter to the return means 160.

According to one embodiment, in a plane containing the directions DL and DR, the front face 162 is domed and comprises, in its upper part, the inclined first surface 164, against which the catch 90 bears in the locked state, as illustrated in FIG. 6, a top 166 against which the catch 90 bears as it passes from the locked state to the unlocked state, as illustrated in FIG. 14A, and, in its lower part, a second inclined surface 168, the inclined surfaces 164 and 168 being approximately symmetric with respect to the sliding axis A158. By way of example, the first inclined surface 164 forms an angle of around 60° with respect to the sliding axis A158.

Preferably, the catch 90 comprise a roller 102 which comes into contact with the stop 92 and which makes it possible to eliminate friction between the catch 90 and said stop 92.

As shown in FIG. 13, each of the cabin 44 and 44′ is more or less leaktight. If depressurization occurs in the pilot cabin 44, there is a sudden and large pressure difference between the pilot cabin 44 and the passenger cabin 44′. This pressure difference has an effect on either side of the internal escape hatch 68. Thus, as shown in FIG. 14A, this pressure difference generates forces f at the external surface 72, said forces f pushing the internal escape hatch 68 towards the inside of the cabin. On account of the forces f, the catch 90 exerts on the stop 92 a force G oriented in the direction DR towards the inside of the cabin. When this force G exceeds a threshold value, the stop 92 retracts and no longer retains the catch 90, which passes into the unlocked state, as illustrated in FIG. 14B. The opening of the internal escape hatch 68 makes it possible to re-establish the equilibrium between the two cabins 44, 44′. In order to give an order of magnitude, the threshold value of the force G is around 218 N.

By virtue of the invention, it is possible, in some aeroplanes, to eliminate pressure regulating systems at the separating wall 47 or the door thereof, thereby reducing the on-board mass. In other aeroplanes, the invention makes it possible to supplement existing pressure regulating systems and thus to increase the effectiveness thereof.

According to another feature, the internal escape hatch 68 is connected to the structure of the aeroplane and more particularly to the frame 74 by at least one strap 170. According to one embodiment, the internal escape hatch 68 is connected to the upper edge 76 of the frame by two straps 170, 170′.

This configuration makes it possible to avoid a situation in which the internal escape hatch 68 injures the person sitting under the latter during the automatic triggering of opening of the internal escape hatch 68 in the event of depressurization of the pilot cabin, as illustrated in FIG. 15.

Advantageously, each strap 170 is connected to the escape hatch 68 by a connection 172 which automatically breaks the link between said internal escape hatch 68 and each strap 170, 170′ when the catch 90 is in the unlocked state. Specifically, the straps 170, 170′ should not impede the opening of the internal escape hatch 68 when the opening thereof is triggered voluntarily by a person pulling on the controller 120.

Preferably, as visible in FIG. 7, each strap 170, 170′ comprises at its end a ring 174. In addition, the shaft 98 which holds the catch 90 comprises, for each strap 170, 170′, a hook 176, the end of which bears against a bearing surface 178 secured to the panel 69 when the catch 90 is in the locked state. According to one embodiment, the yoke 96 comprises two bearing surfaces 178, one for each strap, that are provided on the outside of the cylindrical bearing surfaces 96 a, 96 b. Each hook 176 extends in a plane perpendicular to the rotation axis 94 of the shaft 98, at each end of the shaft 98.

For each strap 170, 170′, in the locked state, the hook 176 passes through the ring 174 and retains it as long as its end is in contact with the corresponding bearing surface 178. Thus, if the opening of the internal escape hatch 68 is triggered on account of depressurization, with the catch 90 still remaining in the locked state, the straps 170, 170′ remain secured to the internal escape hatch 68.

If the opening of the internal escape hatch 68 is triggered voluntarily by a person pulling on the controller 120, then the locking handle 106 frees the shaft 98, which can pivot. The rotation of the shaft 98 causes the catch 90 to pass into the unlocked state and also frees the rings 174, the ends of the hooks 176 being spaced apart from the bearing surfaces 178.

Preferably, each bearing surface 178 comprises a pointed end that is inclined towards the inside of the cabin in order not to retain the ring 174 when each hook 176 is spaced apart from the corresponding bearing surface 178.

According to another function of pressure regulation, the internal escape hatch 68 makes it possible to regulate the pressure in the event of over pressure in the pilot cabin 44.

To this end, the internal escape hatch 68 comprises an opening 180 (visible in FIG. 17B) which makes it possible to bring the inside of the cabin 44 into communication with the intermediate region 182 (visible in FIGS. 3A and 13) between the internal bulkhead 46 and the skin 40 of the fuselage and an overpressure panel 184 configured to close off said opening 180.

Advantageously, the overpressure panel 184 is as large as possible in order that the pressure is distributed over as large a surface area as possible.

Preferably, the opening 180 is at a distance from the peripheral edge face 88 of the internal escape hatch 68.

According to one embodiment, the panel 69 of the internal escape hatch 68 comprises two parts, a peripheral portion 186 which surrounds the opening 180 and a central portion which corresponds to the overpressure panel 184.

The peripheral portion 186 comprises the opening 122 and carries the yokes 96 and 114, the lever 124 and the disconnectable hinges.

According to one embodiment, the opening 180 and the overpressure panel 184 have the same rectangular peripheral shapes with rounded corners.

Advantageously, the overpressure panel 184 is connected to the peripheral portion 186 by a connection 188 which prevents any movement of the overpressure panel 184 towards the inside of the cabin 44 and which allows the overpressure panel 184 to move in the direction of the external escape hatch 50 when a force exerted on the overpressure panel 184 in the direction of the external escape hatch 50 exceeds a particular threshold.

The connection 188 comprises lugs 190 made of ferromagnetic material that are fixed to the external face 191 of the overpressure panel 184 and which protrude from the periphery of said panel 184 so as to be positioned above the peripheral portion 186. The connection 188 also comprises, for each lug 190, a holder 192 fixed to the external surface 194 of the peripheral portion 186, and a magnetic element 196, such as a permanent magnet, for example, fixed to the holder 192, each magnetic element 196 being disposed under a lug 190. The magnetic force exerted by the magnetic elements 196 is adjusted depending on the desired value for the automatic triggering of opening of the overpressure panel in the event of overpressure inside the cabin 44.

Thus, in the absence of overpressure, the lugs 190 bear against the holders 192 and prevent any movement of the overpressure panel 184 towards the inside of the cabin 44. The magnetic elements 196 keep the lugs 198 pressed against their holders 192 and prevent any movement of the overpressure panel 184 towards the outside of the cabin 44. As soon as the overpressure inside the cabin 44 exceeds a particular threshold, the magnetic force of the magnetic elements 196 is insufficient to retain the lugs 190 and the overpressure panel 146 lifts so as to allow equalization of the pressures on either side of the internal escape hatch 68.

Advantageously, the secondary panel 184 comprises water-absorbing elements 198 at its external face 194. According to one embodiment, these water-absorbing elements 198 are in the form of strips that are adhesively bonded to the external face 194 of the overpressure panel 184 and arranged so as to form a barrier configured to limit ingress of water into the pilot cabin 44, in particular during the descent phase of flights.

According to another feature, visible in FIG. 16, the internal escape hatch 68 comprises a centring means 200 for simplifying the positioning of said internal escape hatch 68 with respect to the structure of the aeroplane, and more particularly of the catch 90 with respect to the stop 92.

In order to position the upper edge 202 of the internal escape hatch, a centring pin 204 is fixed close to the upper edge 202, on the external surface 72 of said hatch. In addition, a plate 206 having an oblong slot 208 is fixed to the structure of the aeroplane, more particularly to the frame 74. The oblong slot 208 has a width equal, allowing for play, to the diameter of the centring pin 204 and its length is oriented substantially perpendicularly to the longitudinal direction DL and the direction DR, in a direction parallel to the catch 90.

While at least one exemplary embodiment of the present invention(s) is disclosed herein, it should be understood that modifications, substitutions and alternatives may be apparent to one of ordinary skill in the art and can be made without departing from the scope of this disclosure. This disclosure is intended to cover any adaptations or variations of the exemplary embodiment(s). In addition, in this disclosure, the terms “comprise” or “comprising” do not exclude other elements or steps, the terms “a” or “one” do not exclude a plural number, and the term “or” means either or both. Furthermore, characteristics or steps which have been described may also be used in combination with other characteristics or steps and in any order unless the disclosure or context suggests otherwise. This disclosure hereby incorporates by reference the complete disclosure of any patent or application from which it claims benefit or priority. 

1. An aeroplane comprising an external skin and an internal bulkhead delimiting a cabin, and comprising an escape opening passing through said external skin and said internal bulkhead, said escape opening being closed off by an external escape hatch that is movable between a closed position, in which the escape hatch is disposed flush with the external skin, and an open position, said external escape hatch comprising locking/unlocking means that are controlled by an external opening controller, the aeroplane further comprising: an internal escape hatch that closes off said escape opening flush with the internal bulkhead; at least one catch movable between a locked state and an unlocked state, said catch keeping said internal escape hatch in a closed position in the locked state; a first opening controller configured for controlling the passage from the locked state to the unlocked state of the catch being accessible from inside the aeroplane; a second opening controller configured for controlling the passage from the locked state to the unlocked state of the catch being positioned such that the actuation of the external opening controller of the external escape hatch or the passage of the external escape hatch from the closed position to the open position causes the second opening controller to be actuated.
 2. The aeroplane according to claim 1, wherein the second controller comprises: a pivoting lever; and a cable connecting said pivoting lever to the catch, said pivoting lever and said cable being configured such that, during the actuation of the external opening controller of the external escape hatch or during the passage of the external escape hatch from the closed position to the open position, the pivoting lever pivots and exerts a traction force on the cable, causing the catch to pass from the locked state to the unlocked state.
 3. The aeroplane according to claim 1, wherein the internal escape hatch comprises: at least one return means configured for causing the catch to tilt into the unlocked state; and at least one locking handle movable between a first position corresponding to the locked state of the catch, in which the locking handle immobilizes the catch counter to the one or more return means, and a second position in which the locking handle does not immobilize the catch, which tilts into the unlocked state by virtue of the one or more return means.
 4. The aeroplane according to claim 3, wherein the internal escape hatch comprises at least one return means for keeping the locking handle in the first position.
 5. The aeroplane according to claim 3, wherein the catch comprises at least one arm fixed to a shaft that pivots about a rotation axis with respect to a holder connected to the internal escape hatch, said rotation axis and the arm being configured such that in the locked state, the arm or an element carried by the arm is in contact with a stop, and such that in the unlocked state, the arm or an element carried by the arm is spaced apart from the stop and allows the internal escape hatch to be opened.
 6. The aeroplane according to claim 5, wherein the shaft comprises at least one notch and in that the locking handle comprises at least one protrusion which bears against the notch of the shaft in the locked state.
 7. The aeroplane according to claim 6, wherein the locking handle is able to rotate about a rotation axis and comprises a controller that is spaced apart from the rotation axis by a distance greater than the protrusion(s).
 8. The aeroplane according to claim 2, wherein the locking handle is able to rotate about a rotation axis and comprises a controller that is spaced apart from the rotation axis by a distance greater than the protrusion(s), and wherein the cable is connected to the locking handle.
 9. The aeroplane according to claim 1, wherein the internal escape hatch comprises pressure regulating means which automatically trigger the opening of said internal escape hatch when a pressure difference on either side of said hatch exceeds a given value.
 10. The aeroplane according to claim 5, wherein the internal escape hatch comprises pressure regulating means which automatically trigger the opening of said internal escape hatch when a pressure difference on either side of said hatch exceeds a given value, and wherein the internal escape hatch is connected to the aeroplane by at least one strap.
 11. The aeroplane according to claim 10, wherein, in order to be connected to the internal escape hatch, each strap comprises a ring, and wherein the shaft which supports the catch comprises, for each strap, a hook having an end which bears against a bearing surface when the catch is in the locked state and which is spaced apart from said bearing surface when the catch is in the unlocked state, the hook passing through the ring in the locked state.
 12. The aeroplane according to claim 1, wherein the internal escape hatch comprises, at a first edge, a catch, and, at the opposite edge, two disconnectable hinges.
 13. The aeroplane according to claim 12, wherein the internal escape hatch comprises, at the first edge, a centering pin which engages with an oblong slot which is integral with the aeroplane and has a length parallel to the catch. 